Resource quality affects carbon cycling in deep-sea sediments
Resource quality affects carbon cycling in deep-sea sediments
Deep-sea sediments cover ~70% of Earth's surface and represent the largest interface between the biological and geological cycles of carbon. Diatoms and zooplankton faecal pellets naturally transport organic material from the upper ocean down to the deep seabed, but how these qualitatively different substrates affect the fate of carbon in this permanently cold environment remains unknown. We added equal quantities of 13C-labelled diatoms and faecal pellets to a cold water (?0.7?°C) sediment community retrieved from 1080?m in the Faroe-Shetland Channel, Northeast Atlantic, and quantified carbon mineralization and uptake by the resident bacteria and macrofauna over a 6-day period. High-quality, diatom-derived carbon was mineralized >300% faster than that from low-quality faecal pellets, demonstrating that qualitative differences in organic matter drive major changes in the residence time of carbon at the deep seabed. Benthic bacteria dominated biological carbon processing in our experiments, yet showed no evidence of resource quality-limited growth; they displayed lower growth efficiencies when respiring diatoms. These effects were consistent in contrasting months. We contend that respiration and growth in the resident sediment microbial communities were substrate and temperature limited, respectively. Our study has important implications for how future changes in the biochemical makeup of exported organic matter will affect the balance between mineralization and sequestration of organic carbon in the largest ecosystem on Earth.
bacterial growth efficiency, biogeochemistry, carbon mineralization, deep sea, resource quality, stable isotope
1740-1748
Mayor, Daniel J.
a2a9c29e-ffdc-4858-ad65-3a235824a4c9
Thornton, Barry
6aa3e893-d436-4656-9dec-d47ce9d25219
Hay, Steve
e231fcd3-0714-4c35-ac34-5841e9d5e532
Zuur, Alain F.
5d65336f-0f72-4ea4-aad2-b1d343267ae0
Nicol, Graeme W.
853667ef-e8ca-4831-8c3c-819c3444be3d
McWilliam, Jenna M.
924074a0-dc74-4434-853a-f7e205751796
Witte, Ursula F.M.
3fbf1cd5-11b4-479d-b4ff-15e51bc0e368
2012
Mayor, Daniel J.
a2a9c29e-ffdc-4858-ad65-3a235824a4c9
Thornton, Barry
6aa3e893-d436-4656-9dec-d47ce9d25219
Hay, Steve
e231fcd3-0714-4c35-ac34-5841e9d5e532
Zuur, Alain F.
5d65336f-0f72-4ea4-aad2-b1d343267ae0
Nicol, Graeme W.
853667ef-e8ca-4831-8c3c-819c3444be3d
McWilliam, Jenna M.
924074a0-dc74-4434-853a-f7e205751796
Witte, Ursula F.M.
3fbf1cd5-11b4-479d-b4ff-15e51bc0e368
Mayor, Daniel J., Thornton, Barry, Hay, Steve, Zuur, Alain F., Nicol, Graeme W., McWilliam, Jenna M. and Witte, Ursula F.M.
(2012)
Resource quality affects carbon cycling in deep-sea sediments.
The ISME Journal, 6 (9), .
(doi:10.1038/ismej.2012.14).
Abstract
Deep-sea sediments cover ~70% of Earth's surface and represent the largest interface between the biological and geological cycles of carbon. Diatoms and zooplankton faecal pellets naturally transport organic material from the upper ocean down to the deep seabed, but how these qualitatively different substrates affect the fate of carbon in this permanently cold environment remains unknown. We added equal quantities of 13C-labelled diatoms and faecal pellets to a cold water (?0.7?°C) sediment community retrieved from 1080?m in the Faroe-Shetland Channel, Northeast Atlantic, and quantified carbon mineralization and uptake by the resident bacteria and macrofauna over a 6-day period. High-quality, diatom-derived carbon was mineralized >300% faster than that from low-quality faecal pellets, demonstrating that qualitative differences in organic matter drive major changes in the residence time of carbon at the deep seabed. Benthic bacteria dominated biological carbon processing in our experiments, yet showed no evidence of resource quality-limited growth; they displayed lower growth efficiencies when respiring diatoms. These effects were consistent in contrasting months. We contend that respiration and growth in the resident sediment microbial communities were substrate and temperature limited, respectively. Our study has important implications for how future changes in the biochemical makeup of exported organic matter will affect the balance between mineralization and sequestration of organic carbon in the largest ecosystem on Earth.
This record has no associated files available for download.
More information
Published date: 2012
Keywords:
bacterial growth efficiency, biogeochemistry, carbon mineralization, deep sea, resource quality, stable isotope
Organisations:
Marine Biogeochemistry
Identifiers
Local EPrints ID: 380724
URI: http://eprints.soton.ac.uk/id/eprint/380724
ISSN: 1751-7362
PURE UUID: 44fc9b37-31b6-4c16-bfc8-a052ee0eb13b
Catalogue record
Date deposited: 19 Aug 2015 10:21
Last modified: 14 Mar 2024 21:03
Export record
Altmetrics
Contributors
Author:
Daniel J. Mayor
Author:
Barry Thornton
Author:
Steve Hay
Author:
Alain F. Zuur
Author:
Graeme W. Nicol
Author:
Jenna M. McWilliam
Author:
Ursula F.M. Witte
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics